DE1043750B - Thermal bimetals - Google Patents

Description

Thermobimetals It sometimes exists for special cases of technology the desire for temperature-controlled regulation or for temperature display thermal bimetals to use a sufficiently large deflection with changing temperature and which are also resistant to attack by water vapor and, if necessary are also against the attack of former agents.

This task could not be solved satisfactorily so far because one with thermal bimethalls. relied on it for the side with the low extent was to use metals or alloys, which have a particularly small coefficient of expansion without being able to take into account their susceptibility to corrosion. as iron-nickel alloys in particular came into question, especially iron-nickel with 36% nickel, but also iron-nickel with about 38 to 54% nickel or Iron-nickel-cobalt alloys of suitable composition, e.g. B. 28% Ni, 18% Co, Remainder Fe.

For the side with the high expansion either pure metals were used used, e.g. B. copper or nickel, or alloys based on iron-nickel with additions of 6 to 100 / c, manganese or finally alloys from the manganese-copper-nickel system. Of the latter in particular it is known that they were doubled with iron-nickel with 36 ouzo nickel or with alloys, which contain 20 to 30 "/ o nickel, 30 to 20% cobalt, the remainder being essentially iron. All these bimetals do not meet the requirement that they rust and corrosive, are permanent. In particular for binary iron-nickel alloys, including those with nickel contents between 30 and 40%, they were known to rust and a loose, a thick, granular instep layer and, as a result, they are covered with anti-rust Coatings must be provided when they are exposed to the atmosphere.

The well-known method, the rust resistance by applying top layers, z. B. galvanically applied metal coatings to produce, does not satisfy in all cases and also brings an additional workload, which is caused by the described invention becomes obsolete.

According to the invention, the problem is solved by thermal bimetals solved, in which the side with the high thermal expansion from a known per se Mangam, copper-nickel alloy with 5 to 600 / o copper and 0.5 to 25% nickel, The remainder manganese, bestehr, and the side with the low dimension of a metallic one Material that has a higher rust resistance than binaire iron-nickel alloys. With such bimetals, both components are against the attack of water vapor and Resistant to some-other chemical influences. The components also have sufficiently different expansion coefficients 'so' that they are e.g. B. for regulators can be used that work in water or steam atmosphere.

It is particularly advantageous for the side with the high expansion an alloy with 6 to 15%, in particular 9 to 11% copper, 11 to 2%, in particular 15 to 17 "/ o nickel, 70 to 77%, especially 73 to 75% manganese. Such alloys not only have a high expansion coefficient, but. this high expansion coefficient is in contrast to the expansion coefficient of other manganese-copper-nickel alloys largely independent of the thermal pretreatment. While in general the expansion coefficient of the alloys of the manganese-copper-nickel system is proportionate is subject to strong fluctuations, depending on whether the alloys are cold-worked or annealed and optionally quenched or slowly cooled, d, is e.g. B. the coefficient of expansion for an alloy with 10% copper, 16% nickel and 74% manganese only slightly different after various thermal pretreatments.

As a side with the lower extent, for. B. Nickel or Copper or other rustproof metals or alloys, especially the known ones stainless austenitic chromium-nickel steels with, for example, about 8% Ni, 18 "/ o Cr, the remainder Fe, can be used; H. Materials that are sometimes used in known bimetals for the side with high thermal expansion.

Of course, the deflection of a bimetal that z. B. composed of a manganese-copper-nickel alloy and copper or nickel is, not as big as the curvature of a Bimental, lus made of the same manganese-copper-nickel alloy, which is lined with an iron-nickel alloy with 36% nickel. The curve the designated. Bimetallic is, however, if as a side of lower expansion a material with a coefficient of expansion of less than 200 # 10-7 degrees -1 is selected in the temperature range 0 to 300 ° C, still sufficient for many cases, and the smaller deflection is in practice due to the advantage more. r as outweighed, that the thermal bimetals z. B. used in contact with water or in a steam atmosphere can be what was not possible with previously known bimetals.

As an example it should be given that a Thsrmobimetall, one side of which consists of an alloy of 10% copper, 16% nickel and 74% manganese and its the other side consists of pure nickel, a specific deflection of 0.100 im Has a temperature range of 0 to 100 ° C. Is below the specific curvature the way, measured in mm, understood that the free end of a cantilevered scihmalen straight strips 100 mm long and 1 mm thick with an increase in temperature of 1 ° C.

Such bimetals have a largely straight expansion curve up to temperatures of around 500 ° C.

Claims (8)

P A T E N T A N S P R Ü C H E: 1. Thermal bimetal, characterized that the side with the high thermal expansion is made of a known manganese-copper-nickel alloy with 5 to 60% copper and 0.5 to 25% nickel, the remainder being manganese, and the side with the low expansion of a metallic different material, the one higher Rust resistance possesses as binary iron-nickel alloys. 2. Thermal bimetal according to claim 1, characterized in that the side with high thermal expansion from an alloy with 6 to 15% copper, 11 to 211 / o, Nickel, 70 to 77 per cent. Manganese. 3. thermal bimetal according to claim 1 and 2, characterized gekennziehcnet, that the side of smaller extension is made of a rust-resistant metal or a rust-resistant Alloy with a coefficient of expansion of less than 200 # 10-7 degree-1 im Temperature range 0 to 300 ° C. 4. thermal bimetal according to claim 3, characterized in that the side with the lower expansion is made of nickel. 5. thermal bimetal according to claim 3, characterized in that the The side with the lower dimension is made of copper. 6. Thermal bimetal after. Claim 3, characterized in that the Side with the lower thermal expansion made of stainless austenitic chrome-nickel steel consists. .7.Thermobimeta.llnach.Anspruch 6, characterized in that the Side with the lower thermal expansion made of a steel with 8% nickel, 18% chromium, Remainder iron. 8. Use of thermal bimetals according to claim 1 to 7 in water or atmosphere containing water vapor. Publications considered: H. H. Uh lig, "Corrosion Handbook", New York, 1948, p. 200; "Metals Handbook", 1948, p. 476.